Rare earth metal compounds, methods of making, and methods of using the same

ABSTRACT

Rare earth metal compounds, particularly lanthanum, cerium, and yttrium, are formed as porous particles and are effective in binding metals, metal ions, and phosphate. A method of making the particles and a method of using the particles is disclosed. The particles may be used in the gastrointestinal tract or the bloodstream to remove phosphate or to treat hyperphosphatemia in mammals. The particles may also be used to remove metals from fluids such as water.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. application Ser. No. 14/149,299 filed Jan. 7, 2014, which is a divisional of U.S. application Ser. No. 12/643,059, filed Dec. 21, 2009, now U.S. Pat. No. 8,715,603, which is a continuation of U.S. application Ser. No. 11/217,001, filed Aug. 31, 2005, now abandoned, which is a continuation-in-part of U.S. application Ser. No. 10/444,774, filed May 23, 2003 (now abandoned), which claims the benefit of the filing dates of U.S. Provisional Application No. 60/396,989, filed May 24, 2002, U.S. Provisional Application No. 60/403,868, filed Aug. 14, 2002, U.S. Provisional Application No. 60/430,284, filed Dec. 2, 2002, and U.S. Provisional Application No. 60/461,175, filed Apr. 8, 2003, the entire disclosures of which applications are hereby incorporated herein by reference.

The present invention relates to rare earth metal compounds, particularly rare earth metal compounds having a porous structure. The present invention also includes methods of making the porous rare earth metal compounds and methods of using the compounds of the present invention. The compounds of the present invention can be used to bind or absorb metals such as arsenic, selenium, antimony and metal ions such as arsenic III⁺ and V⁺. The compounds of the present invention may therefore find use in water filters or other devices or methods to remove metals and metal ions from fluids, especially water.

The compounds of the present invention are also useful for binding or absorbing anions such as phosphate in the gastrointestinal tract of mammals. Accordingly, one use of the compounds of the present invention is to treat high serum phosphate levels in patients with end-stage renal disease undergoing kidney dialysis. In this aspect, the compounds may be provided in a filter that is fluidically connected with a kidney dialysis machine such that the phosphate content in the blood is reduced after passing through the filter.

In another aspect, the compounds can be used to deliver a lanthanum or other rare-earth metal compound that will bind phosphate present in the gut and prevent its transfer into the bloodstream. Compounds of the present invention can also be used to deliver drugs or to act as a filter or absorber in the gastrointestinal tract or in the blood stream. For example, the materials can be used to deliver inorganic chemicals in the gastrointestinal tract or elsewhere.

It has been found that the porous particle structure and the high surface area are beneficial to high absorption rates of anions. Advantageously, these properties permit the compounds of the present invention to be used to bind phosphate directly in a filtering device fluidically connected with kidney dialysis equipment.

The use of rare earth hydrated oxides, particularly hydrated oxides of La, Ce, and Y to bind phosphate is disclosed in Japanese published patent application 61-004529 (1986). Similarly, U.S. Pat. No. 5,968,976 discloses a lanthanum carbonate hydrate to remove phosphate in the gastrointestinal tract and to treat hyperphosphatemia in patients with renal failure. It also shows that hydrated lanthanum carbonates with about 3 to 6 molecules of crystal water provide the highest removal rates. U.S. Pat. No. 6,322,895 discloses a form of silicon with micron-sized or nano-sized pores that can be used to release drugs slowly in the body. U.S. Pat. No. 5,782,792 discloses a method for the treatment of rheumatic arthritis where a “protein A immunoadsorbent” is placed on silica or another inert binder in a cartridge to physically remove antibodies from the bloodstream.

It has now unexpectedly been found that the specific surface area of compounds according to the present invention as measured by the BET method, varies depending on the method of preparation, and has a significant effect on the properties of the product. As a result, the specific properties of the resulting compound can be adjusted by varying one or more parameters in the method of making the compound. In this regard, the compounds of the present invention have a BET specific surface area of at least about 5 m²/g or 10 m²/g and may have a BET specific surface area of at least about 20 m²/g and alternatively may have a BET specific surface area of at least about 35 m²/g. In one embodiment, the compounds have a BET specific surface area within the range of about 10 m²/g and about 40 m²/g.

It has also been found that modifications in the preparation method of the rare earth compounds will create different entities, e.g. different kinds of hydrated or amorphous oxycarbonates or carbonate hydroxides rather than carbonates, and that these compounds have distinct and improved properties. It has also been found that modifications of the preparation method create different porous physical structures with improved properties.

The compounds of the present invention and in particular, the lanthanum compounds and more particularly the lanthanum oxycarbonates and lanthanum carbonate hydroxides of the present invention exhibit phosphate binding or removal of at least 40% of the initial concentration of phosphate after ten minutes. Desirably, the lanthanum compounds exhibit phosphate binding or removal of at least 60% of the initial concentration of phosphate after ten minutes. In other words, the lanthanum compounds and in particular, the lanthanum compounds and more particularly the lanthanum oxycarbonates and lanthanum carbonate hydroxides of the present invention exhibit a phosphate binding capacity of at least 45 mg of phosphate per gram of lanthanum compound. Suitably, the lanthanum compounds exhibit a phosphate binding capacity of at least 50 mg PO₄/g of lanthanum compound, more suitably, a phosphate binding capacity of at least 75 mg PO₄/g of lanthanum compound. Desirably, the lanthanum compounds exhibit a phosphate binding capacity of at least 100 mg PO₄/g of lanthanum compound, more desirably, a phosphate binding capacity of at least 110 mg PO₄/g of lanthanum compound.

In accordance with the present invention, rare earth metal compounds, and in particular, rare earth metal oxychlorides, carbonate hydroxides and oxycarbonates are provided. The oxycarbonates and carbonate hydroxides may be hydrated or anhydrous. These compounds may be produced according to the present invention as particles having a porous structure. The rare earth metal compound particles of the present invention may conveniently be produced within a controllable range of surface areas with resultant variable and controllable adsorption rates of ions.

The porous particles or porous structures of the present invention are made of nano-sized to micron-sized crystals with controllable surface areas. The rare earth oxychloride is desirably lanthanum oxychloride (LaOCl). The rare earth oxycarbonate hydrate is desirably lanthanum oxycarbonate hydrate (La₂O(CO₃)₂.xH₂O where x is from and including 2 to and including 4). This compound will further be referred to in this text as La₂O(CO₃)₂.xH₂O. The anhydrous rare earth oxycarbonate is desirably lanthanum oxycarbonate La₂O₂CO₃ or La₂CO₅ of which several crystalline forms exist. The lower temperature form will be identified as La₂O₂CO₃ and the form obtained at higher temperature or after a longer calcination time will be identified as La₂CO₅. The rare earth carbonate hydroxide is desirably lanthanum carbonate hydroxide LaCO₃OH.

One skilled in the art, however, will understand that lanthanum oxycarbonate may be present as a mixture of the hydrate and the anhydrous form. In addition, the anhydrous lanthanum oxycarbonate may be present as a mixture of La₂O₂CO₃ and La₂CO₅ and may be present in more than a single crystalline form.

One method of making the rare earth metal compound particles includes making a solution of rare earth metal chloride, subjecting the solution to a substantially total evaporation process using a spray dryer or other suitable equipment to form an intermediate product, and calcining the obtained intermediate product at a temperature between about 500° and about 1200° C. The product of the calcination step may be washed, filtered, and dried to make a suitable finished product. Optionally, the intermediate product may be milled in a horizontal or vertical pressure media mill to a desired surface area and then further spray dried or dried by other means to produce a powder that may be further washed and filtered.

An alternative method of making the rare earth metal compounds, particularly rare earth metal anhydrous oxycarbonate particles includes making a solution of rare earth metal acetate, subjecting the solution to a substantially total evaporation process using a spray dryer or other suitable equipment to make an intermediate product, and calcining the obtained intermediate product at a temperature between about 400° C. and about 700° C. The product of the calcination step may be washed, filtered, and dried to make a suitable finished product. Optionally, the intermediate product may be milled in a horizontal or vertical pressure media mill to a desired surface area, spray dried or dried by other means to produce a powder that may be washed, filtered, and dried.

Yet another method of making the rare earth metal compounds includes making rare earth metal oxycarbonate hydrate or rare earth carbonate hydroxide particles. The rare earth metal oxycarbonate hydrate or rare earth carbonate hydroxide particles can be made by successively making a solution of rare earth chloride, subjecting the solution to a slow, steady feed of a sodium carbonate solution at a temperature between about 30° and about 90° C. while mixing, then filtering and washing the precipitate to form a filter cake, then drying the filter cake at a temperature of about 100° to 120° C. to produce the desired rare earth oxycarbonate hydrate or rare earth carbonate hydroxide species. Optionally, the filter cake may be sequentially dried, slurried, and milled in a horizontal or vertical pressure media mill to a desired surface area, spray dried or dried by other means to produce a powder that may be washed, filtered, and dried.

Alternatively, the process for making rare earth metal oxycarbonate hydrate particles may be modified to produce anhydrous particles. This modification includes subjecting the dried filter cake to a thermal treatment at a specified temperature between about 400° C. to about 700° C. and for a specified time between 1 h and 48 h. Optionally, the product of the thermal treatment may be slurried and milled in a horizontal or vertical pressure media mill to a desired surface area, spray dried or dried by other means to produce a powder that may be washed, filtered, and dried.

In accordance with the present invention, compounds of the present invention may be used to treat patients with hyperphosphatemia. The compounds may be made into a form that may be delivered to a mammal and that may be used to remove phosphate from the gut or decrease phosphate absorption into the blood stream. For example, the compounds may be formulated to provide an orally ingestible form such as a liquid solution or suspension, a tablet, capsule, gelcap, or other suitable and known oral form. Accordingly, the present invention contemplates a method for treating hyperphosphatemia that comprises providing an effective amount of a compound of the present invention. Compounds made under different conditions will correspond to different oxycarbonates, carbonate hydroxides or oxychlorides, will have different surface areas, and will show differences in reaction rates with phosphate and different solubilization of lanthanum or another rare-earth metal into the gut. The present invention allows one to modify these properties according to the requirements of the treatment.

In another aspect of the present invention, compounds made according to this invention as a porous structure of sufficient mechanical strength may be placed in a device fluidically connected to a dialysis machine through which the blood flows, to directly remove phosphate by reaction of the rare-earth compound with phosphate in the bloodstream. The present invention therefore contemplates a device having an inlet and an outlet with one or more compounds of the present invention disposed between the inlet and the outlet. The present invention also contemplates a method of reducing the amount of phosphate in blood that comprises contacting the blood with one or more compounds of the present invention for a time sufficient to reduce the amount of phosphate in the blood.

In yet another aspect of the present invention, the compounds of the present invention may be used as a substrate for a filter having an inlet and outlet such that the compounds of the present invention are disposed between the inlet and the outlet. A fluid containing a metal, metal ion, phosphate or other ion may be passed from the inlet to contact the compounds of the present invention and through the outlet. Accordingly, in one aspect of the present invention a method of reducing the content of a metal in a fluid, for example water, comprises flowing the fluid through a filter that contains one or more compounds of the present invention to reduce the amount of metal present in the water.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a general flow sheet of a process according to the present invention that produces LaOCl (lanthanum oxychloride).

FIG. 2 is a flow sheet of a process according to the present invention that produces a coated titanium dioxide structure.

FIG. 3 is a flow sheet of a process according to the present invention that produces lanthanum carbonate hydroxide.

FIG. 4 is a graph showing the percentage of phosphate removed from a solution as a function of time by LaCO₃OH made according to the process of the present invention, as compared to the percentage of phosphate removed by commercial grade La carbonate La₂(CO₃)₃.4H₂O in the same conditions.

FIG. 5 is a graph showing the amount of phosphate removed from a solution as a function of time per g of a lanthanum compound used as a drug to treat hyperphosphatemia. The drug in one case is LaCO₃OH made according to the process of the present invention. In the comparative case the drug is commercial grade La carbonate La₂(CO₃)₃.4H₂O.

FIG. 6 is a graph showing the amount of phosphate removed from a solution as a function of time per g of a lanthanum compound used as a drug to treat hyperphosphatemia. The drug in one case is La₂O₂CO₃ made according to the process of the present invention. In the comparative case the drug is commercial grade La carbonate La₂(CO₃)₃.4H₂O.

FIG. 7 is a graph showing the percentage of phosphate removed as a function of time by La₂O₂CO₃ made according to the process of the present invention, as compared to the percentage of phosphate removed by commercial grade La carbonate La₂(CO₃)₃.4H₂O.

FIG. 8 is a graph showing a relationship between the specific surface area of the oxycarbonates or carbonate hydroxides made following the process of the present invention and the amount of phosphate bound or removed from solution 10 min after the addition of the oxycarbonate or carbonate hydroxide.

FIG. 9 is a graph showing a linear relationship between the specific surface area of the oxycarbonates or carbonate hydroxides of this invention and the first order rate constant calculated from the initial rate of reaction of phosphate.

FIG. 10 is a flow sheet of a process according to the present invention that produces lanthanum carbonate hydroxide LaCO₃OH.

FIG. 11 is a flow sheet of a process according to the present invention that produces anhydrous lanthanum oxycarbonate La₂O₂CO₃ or La₂CO₅.

FIG. 12 is a scanning electron micrograph of lanthanum oxychloride, made following the process of the present invention.

FIG. 13 is an X-Ray diffraction scan of lanthanum oxychloride LaOCl made according to the process of the present invention and compared with a standard library card of lanthanum oxychloride.

FIG. 14 is a graph showing the percentage of phosphate removed from a solution as a function of time by LaOCl made according to the process of the present invention, as compared to the amount of phosphate removed by commercial grades of La carbonate La₂(CO₃)₃.H₂O and La₂(CO₃)₃.4H₂O in the same conditions.

FIG. 15 shows a scanning electron micrograph of LaCO₃OH.

FIG. 16 is an X-Ray diffraction scan of LaCO₃OH produced according to the present invention and includes a comparison with a “library standard” of La₂O(CO₃)₂.xH₂O where x is from and including 2 to and including 4.

FIG. 17 is a graph showing the rate of removal of phosphorous from a solution by LaCO₃OH compared to the rate obtained with commercially available La₂(CO₃)₃.H₂O and La₂(CO₃)₃.4H₂O in the same conditions.

FIG. 18 is a scanning electron micrograph of anhydrous lanthanum oxycarbonate La₂O₂CO₃.

FIG. 19 is an X-Ray diffraction scan of anhydrous La₂O₂CO₃ produced according to the present invention and includes a comparison with a “library standard” of La₂O₂CO₃.

FIG. 20 is a graph showing the rate of phosphorous removal obtained with La₂O₂CO₃ made following the process of the present invention and compared to the rate obtained for commercially available La₂(CO₃)₃.H₂O and La₂(CO₃)₃.4H₂O.

FIG. 21 is a scanning electron micrograph of La₂CO₅ made according to the process of the present invention.

FIG. 22 is an X-Ray diffraction scan of anhydrous La₂CO₅ produced according to the present invention and includes a comparison with a “library standard” of La₂CO₅.

FIG. 23 is a graph showing the rate of phosphorous removal obtained with La₂CO₅ made following the process of the present invention and compared to the rate obtained for commercially available La₂(CO₃)₃.H₂O and La₂(CO₃)₃.4H₂O.

FIG. 24 is a scanning electron micrograph of TiO₂ support material made according to the process of the present invention.

FIG. 25 is a scanning electron micrograph of a TiO₂ structure coated with LaOCl, made according to the process of the present invention, calcined at 800° C.

FIG. 26 is a scanning electron micrograph of a TiO₂ structure coated with LaOCl, made according to the process of the present invention, calcined at 600° C.

FIG. 27 is a scanning electron micrograph of a TiO₂ structure coated with LaOCl, made according to the process of the present invention, calcined at 900° C.

FIG. 28. shows X-Ray scans for TiO₂ coated with LaOCl and calcined at different temperatures following the process of the present invention, and compared to the X-Ray scan for pure LaOCl.

FIG. 29 shows the concentration of lanthanum in blood plasma as a function of time, for dogs treated with lanthanum oxycarbonates or lanthanum carbonate hydroxides made according to the process of the present invention.

FIG. 30 shows the concentration of phosphorous in urine as a function of time in rats treated with lanthanum oxycarbonates or lanthanum carbonate hydroxides made according to the process of the present invention, and compared to phosphorus concentration measured in untreated rats.

FIG. 31 shows a device having an inlet, an outlet, and one or more compounds of the present invention disposed between the inlet and the outlet.

DESCRIPTION OF THE INVENTION

Referring now to the drawings, the process of the present invention will be described. While the description will generally refer to lanthanum compounds, the use of lanthanum is merely for ease of description and is not intended to limit the invention and claims solely to lanthanum compounds. In fact, it is contemplated that the process and the compounds described in the present specification is equally applicable to rare earth metals other than lanthanum such as Ce and Y.

Turning now to FIG. 1, a process for making a rare earth oxychloride compound, and, in particular a lanthanum oxychloride compound according to one embodiment of the present invention is shown. First, a solution of lanthanum chloride is provided. The source of lanthanum chloride may be any suitable source and is not limited to any particular source. One source of lanthanum chloride solution is to dissolve commercial lanthanum chloride crystals in water or in an HCl solution. Another source is to dissolve lanthanum oxide in a hydrochloric acid solution.

The lanthanum chloride solution is evaporated to form an intermediate product. The evaporation 20 is conducted under conditions to achieve substantially total evaporation. Desirably, the evaporation is conducted at a temperature higher than the boiling point of the feed solution (lanthanum chloride) but lower than the temperature where significant crystal growth occurs. The resulting intermediate product may be an amorphous solid formed as a thin film or may have a spherical shape or a shape as part of a sphere.

The terms “substantially total evaporation” or “substantially complete evaporation” as used in the specification and claims refer to evaporation such that the resulting solid intermediate contains less than 15% free water, desirably less than 10% free water, and more desirably less than 1% free water. The term “free water” is understood and means water that is not chemically bound and can be removed by heating at a temperature below 150° C. After substantially total evaporation or substantially complete evaporation, the intermediate product will have no visible moisture present.

The evaporation step may be conducted in a spray dryer. In this case, the intermediate product will consist of a structure of spheres or parts of spheres. The spray dryer generally operates at a discharge temperature between about 120° C. and about 500° C.

The intermediate product may then be calcined in any suitable calcination apparatus 30 by raising the temperature to a temperature between about 500° C. to about 1200° C. for a period of time from about 2 to about 24 h and then cooling to room temperature. The cooled product may be washed 40 by immersing it in water or dilute acid, to remove any water-soluble phase that may still be present after the calcination step 30.

The temperature and the length of time of the calcination process may be varied to adjust the particle size and the reactivity of the product. The particles resulting from calcination generally have a size between 1 and 1000 μm. The calcined particles consist of individual crystals, bound together in a structure with good physical strength and a porous structure. The individual crystals forming the particles generally have a size between 20 nm and 10 μm.

In accordance with another embodiment of the present invention as shown in FIG. 2, a feed solution of titanium chloride or titanium oxychloride is provided by any suitable source. One source is to dissolve anhydrous titanium chloride in water or in a hydrochloric acid solution. Chemical control agents or additives 104 may be introduced to this feed solution to influence the crystal form and the particle size of the final product. One chemical additive is sodium phosphate Na₃PO₄. The feed solution of titanium chloride or titanium oxychloride is mixed with the optional chemical control agent 104 in a suitable mixing step 110. The mixing may be conducted using any suitable known mixer.

The feed solution is evaporated to form an intermediate product, which in this instance is titanium dioxide (TiO₂). The evaporation 120 is conducted at a temperature higher than the boiling point of the feed solution but lower than the temperature where significant crystal growth occurs and to achieve substantially total evaporation. The resulting intermediate product may desirably be an amorphous solid formed as a thin film and may have a spherical shape or a shape as part of a sphere.

The intermediate product may then be calcined in any suitable calcination apparatus 130 by raising the temperature to a temperature between about 400° C. to about 1200° C. for a period of time from about 2 to about 24 h and then cooling to room temperature (25° C.). The cooled product is then washed 140 by immersing it in water or dilute acid, to remove traces of any water-soluble phase that may still be present after the calcination step.

The method of manufacture of the intermediate product according to the present invention can be adjusted and chosen to make a structure with the required particle size and porosity. For example, the evaporation step 120 and the calcination step 130 can be adjusted for this purpose. The particle size and porosity can be adjusted to make the structure of the intermediate product suitable to be used as an inert filter in the bloodstream.

The washed TiO₂ product is then suspended or slurried in a solution of an inorganic compound. A desirable inorganic compound is a rare-earth or lanthanum compound, and in particular lanthanum chloride. This suspension of TiO₂ in the inorganic compound solution is again subjected to total evaporation 160 under conditions in the same range as defined in step 120 and to achieve substantially total evaporation. In this regard, the evaporation steps 120 and 160 may be conducted in a spray drier. The inorganic compound will precipitate as a salt, an oxide, or an oxy-salt. If the inorganic compound is lanthanum chloride, the precipitated product will be lanthanum oxychloride. If the original compound is lanthanum acetate, the precipitated product will be lanthanum oxide.

The product of step 160 is further calcined 170 at a temperature between 500° and 1100° C. for a period of 2 to 24 h. The temperature and the time of the calcination process influence the properties and the particle size of the product. After the second calcination step 170, the product may be washed 180.

The resulting product can be described as crystals of lanthanum oxychloride or lanthanum oxide formed on a TiO₂ substrate. The resulting product may be in the form of hollow thin-film spheres or parts of spheres. The spheres will have a size of about 1 μm to 1000 μm and will consist of a structure of individual bound particles. The individual particles have a size between 20 nm and 10 μm.

When the final product consists of crystals of lanthanum oxychloride on a TiO₂ substrate, these crystals may be hydrated. It has been found that this product will effectively react with phosphate and bind it as an insoluble compound. It is believed that, if this final product is released in the human stomach and gastrointestinal tract, the product will bind the phosphate that is present and decrease the transfer of phosphate from the stomach and gastrointestinal tract to the blood stream. Therefore, the product of this invention may be used to limit the phosphorous content in the bloodstream of patients on kidney dialysis.

According to another embodiment of the present invention, a process for making anhydrous lanthanum oxycarbonate or lanthanum carbonate hydroxide is shown in FIG. 3. In this process, a solution of lanthanum acetate is made by any method. One method to make the lanthanum acetate solution is to dissolve commercial lanthanum acetate crystals in water or in an HCl solution.

The lanthanum acetate solution is evaporated to form an intermediate product. The evaporation 220 is conducted at a temperature higher than the boiling point of the lanthanum acetate solution but lower than the temperature where significant crystal growth occurs and under conditions to achieve substantially total evaporation. The resulting intermediate product may desirably be an amorphous solid formed as a thin film and may have a spherical shape or a shape as part of a sphere.

The intermediate product may then be calcined in any suitable calcination apparatus 230 by raising the temperature to a temperature between about 400° C. to about 800° C. for a period of time from about 2 to about 24 h and then cooled to room temperature. The cooled product may be washed 240 by immersing it in water or dilute acid, to remove any water-soluble phase that may still be present after the calcination step. The temperature and the length of time of the calcination process may be varied to adjust the particle size and the reactivity of the product.

The particles resulting from the calcination generally have a size between 1 and 1000 μm. The calcined particles consist of individual crystals, bound together in a structure with good physical strength and a porous structure. The individual crystals generally have a size between 20 nm and 10 μm.

The products made by methods shown in FIGS. 1, 2, and 3 comprise ceramic particles with a porous structure. Individual particles are in the micron size range. The particles are composed of crystallites in the nano-size range, fused together to create a structure with good strength and porosity.

The particles made according to the process of the present invention, have the following common properties:

a. They have low solubility in aqueous solutions, especially serum and gastrointestinal fluid, compared to non-ceramic compounds.

b. Their hollow shape gives them a low bulk density compared to solid particles. Lower density particles are less likely to cause retention in the gastro-intestinal tract.

c. They have good phosphate binding kinetics. The observed kinetics are generally better than the commercial carbonate hydrates La₂(CO₃)₃.H₂O and La₂(CO₃)₃.4H₂O. In the case of lanthanum oxychloride, the relationship between the amount of phosphate bound or absorbed and time tends to be closer to linear than for commercial hydrated lanthanum carbonates. The initial reaction rate is lower but does not significantly decrease with time over an extended period. This behavior is defined as linear or substantially linear binding kinetics. This is probably an indication of more selective phosphate binding in the presence of other anions.

d. Properties a, b, and c, above are expected to lead to less gastro-intestinal tract complications than existing products.

e. Because of their particular structure and low solubility, the products of the present invention have the potential to be used in a filtration device placed directly in the bloodstream.

Different lanthanum oxycarbonates have been prepared by different methods. It has been found that, depending on the method of preparation, lanthanum oxycarbonate compounds with widely different reaction rates are obtained.

A desirable lanthanum carbonate hydroxide is LaCO₃OH. This lanthanum carbonate hydroxide is preferred because it exhibits a relatively high rate of removal of phosphate. To determine the reactivity of the lanthanum carbonate hydroxide compound with respect to phosphate, the following procedure was used. A stock solution containing 13.75 g/l of anhydrous Na₂HPO₄ and 8.5 g/l of HCl is prepared. The stock solution is adjusted to pH 3 by the addition of concentrated HCl. 100 ml of the stock solution is placed in a beaker with a stirring bar. A sample of lanthanum carbonate hydroxide powder is added to the solution. The amount of lanthanum carbonate hydroxide powder is such that the amount of La in suspension is 3 times the stoichiometric amount needed to react completely with the phosphate. Samples of the suspension are taken at intervals, through a filter that separated all solids from the liquid. The liquid sample is analyzed for phosphorous. FIG. 4 shows that after 10 min, LaCO₃OH has removed 86% of the phosphate in solution, whereas a commercial hydrated La carbonate La₂(CO₃)₃.4H₂O removes only 38% of the phosphate in the same experimental conditions after the same time.

FIG. 5 shows that the LaCO₃OH depicted in FIG. 4 has a capacity of phosphate removal of 110 mg PO₄ removed/g of La compound after 10 min in the conditions described above, compared to 45 mg PO₄/g for the commercial La carbonate taken as reference.

Another preferred lanthanum carbonate is the anhydrous La oxycarbonate La₂O₂CO₃. This compound is preferred because of its particularly high binding capacity for phosphate, expressed as mg PO₄ removed/g of compound. FIG. 6 shows that La₂O₂CO₃ binds 120 mg PO₄/g of La compound after 10 min, whereas La₂(CO₃)₃.4H₂O used as reference only binds 45 mg PO₄/g La compound.

FIG. 7 shows the rate of reaction with phosphate of the oxycarbonate La₂O₂CO₃. After 10 min of reaction, 73% of the phosphate had been removed, compared to 38% for commercial lanthanum carbonate used as reference.

Samples of different oxycarbonates have been made by different methods as shown in Table 1 below.

TABLE 1 Initial Example Fraction 1^(st) number of order corresponding BET PO₄ rate to surface remaining constant Sam- manufacturing area after k₁ ple Compound method m²/g 10 min (min⁻¹) 1 LaCO₃OH 11 41.3 0.130 0.949 2 LaCO₃OH 11 35.9 0.153 0.929 3 LaCO₃OH 11 38.8 0.171 0.837 4 La₂CO₅ (4 h 7 25.6 0.275 0.545 milling) 5 La₂O₂CO₃ 5 18 0.278 0.483 6 La₂CO₅ (2 h 7 18.8 0.308 0.391 milling) 7 La₂O₂CO₃ 7 16.5 0.327 0.36 8 La₂CO₅ (no 5 11.9 0.483 0.434 milling) 9 La₂(CO₃)₃•4H₂O Commercial 4.4 0.623 0.196 sample 10 La₂(CO₃)₃•1H₂O Commercial 2.9 0.790 0.094 sample

For each sample, the surface area measured by the BET method and the fraction of phosphate remaining after 10 min of reaction have been tabulated. The table also shows the rate constant k₁ corresponding to the initial rate of reaction of phosphate, assuming the reaction is first order in phosphate concentration. The rate constant k₁ is defined by the following equation:

d[PO₄ ]/dt=−k ₁[PO₄]

where [PO₄] is the phosphate concentration in solution (mol/liter), t is time (min) and k₁ is the first order rate constant (min⁻¹). The table gives the rate constant for the initial reaction rate, i.e. the rate constant calculated from the experimental points for the first minute of the reaction.

FIG. 8 shows that there is a good correlation between the specific surface area and the amount of phosphate reacted after 10 min. It appears that in this series of tests, the most important factor influencing the rate of reaction is the surface area, independently of the composition of the oxycarbonate or carbonate hydroxide or the method of manufacture. A high surface area can be achieved by adjusting the manufacturing method or by milling a manufactured product.

FIG. 9 shows that a good correlation is obtained for the same compounds by plotting the first order rate constant as given in Table I and the BET specific surface area. The correlation can be represented by a straight line going through the origin. In other words, within experimental error, the initial rate of reaction appears to be proportional to the phosphate concentration and also to the available surface area.

Without being bound by any theory, for the oxycarbonate, it is proposed that the observed dependence on surface area and phosphate concentration may be explained by a nucleophilic attack of the phosphate ion on the La atom in the oxycarbonate, with resultant formation of lanthanum phosphate LaPO₄. For example, if the oxycarbonate is La₂O₂CO₃, the reaction will be: 1/2La₂O₂CO₃+PO₄ ³⁻+2H₂O→LaPO₄+1/2H₂CO₃+3OH⁻

If the rate is limited by the diffusion of the PO₄ ³⁻ ion to the surface of the oxycarbonate and the available area of oxycarbonate, the observed relationship expressed in FIG. 9 can be explained. This mechanism does not require La to be present as a dissolved species. The present reasoning also provides an explanation for the decrease of the reaction rate after the first minutes: the formation of lanthanum phosphate on the surface of the oxycarbonate decreases the area available for reaction.

In general, data obtained at increasing pH show a decrease of the reaction rate. This may be explained by the decrease in concentration of the hydronium ion (H₃O⁺), which may catalyze the reaction by facilitating the formation of the carbonic acid molecule from the oxycarbonate. Or, it may be simply explained in that the compound is more soluble at lower pHs that higher pHs, which allows it to react faster.

Turning now to FIG. 10, another process for making lanthanum carbonate hydroxide is shown. First, an aqueous solution of lanthanum chloride is made by any method. One method to make the solution is to dissolve commercial lanthanum chloride crystals in water or in an HCl solution. Another method to make the lanthanum chloride solution is to dissolve lanthanum oxide in a hydrochloric acid solution.

The LaCl₃ solution is placed in a well-stirred tank reactor. The LaCl₃ solution is then heated to 80° C. A previously prepared analytical grade sodium carbonate is steadily added over a period of 2 hours with vigorous mixing. The mass of sodium carbonate required is calculated at 6 moles of sodium carbonate per 2 moles of LaCl₃. When the required mass of sodium carbonate solution is added, the resultant slurry or suspension is allowed to cure for 2 hours at 80° C. The suspension is then filtered and washed with demineralized water to produce a clear filtrate. The filter cake is placed in a convection oven at 105° C. for 2 hours or until a stable weight is observed. The initial pH of the LaCl₃ solution is 2, while the final pH of the suspension after cure is 5.5. A white powder is produced. The resultant powder is a lanthanum carbonate hydroxide.

Turning now to FIG. 11 another process for making anhydrous lanthanum oxycarbonate is shown. First, an aqueous solution of lanthanum chloride is made by any method. One method to make the solution is to dissolve commercial lanthanum chloride crystals in water or in an HCl solution. Another method to make the lanthanum chloride solution is to dissolve lanthanum oxide in a hydrochloric acid solution.

The LaCl₃ solution is placed in a well-stirred tank reactor. The LaCl₃ solution is then heated to 80° C. A previously prepared analytical grade sodium carbonate is steadily added over 2 hours with vigorous mixing. The mass of sodium carbonate required is calculated at 6 moles of sodium carbonate per 2 moles of LaCl₃. When the required mass of sodium carbonate solution is added the resultant slurry or suspension is allowed to cure for 2 hours at 80° C. The suspension is then washed and filtered removing NaCl (a byproduct of the reaction) to produce a clear filtrate. The filter cake is placed in a convection oven at 105° C. for 2 hours or until a stable weight is observed. The initial pH of the LaCl₃ solution is 2.2, while the final pH of the suspension after cure is 5.5. A white lanthanum carbonate hydroxide powder is produced. Next the lanthanum carbonate hydroxide is placed in an alumina tray, which is placed in a high temperature muffle furnace. The white powder is heated to 500° C. and held at that temperature for 3 hours. Anhydrous La₂C₂O₃ is formed.

Alternatively, the anhydrous lanthanum oxycarbonate formed as indicated in the previous paragraph may be heated at 500° C. for 15 to 24 h instead of 3 h or at 600° C. instead of 500° C. The resulting product has the same chemical formula, but shows a different pattern in an X-Ray diffraction scan and exhibits a higher physical strength and a lower surface area. The product corresponding to a higher temperature or a longer calcination time is defined here as La₂CO₅.

Turning now to FIG. 31, a device 500 having an inlet 502 and an outlet 504 is shown. The device 500 may be in the form of a filter or other suitable container. Disposed between the inlet 502 and the outlet 504 is a substrate 506 in the form of a plurality of one or more compounds of the present invention. The device may be fluidically connected to a dialysis machine through which the blood flows, to directly remove phosphate by reaction of the rare-earth compound with phosphate in the bloodstream. In this connection, the present invention also contemplates a method of reducing the amount of phosphate in blood that comprises contacting the blood with one or more compounds of the present invention for a time sufficient to reduce the amount of phosphate in the blood.

In yet another aspect of the present invention, the device 500 may be provided in a fluid stream so that a fluid containing a metal, metal ion, phosphate or other ion may be passed from the inlet 502 through the substrate 506 to contact the compounds of the present invention and out the outlet 504. Accordingly, in one aspect of the present invention a method of reducing the content of a metal in a fluid, for example water, comprises flowing the fluid through a device 500 that contains one or more compounds of the present invention to reduce the amount of metal present in the water.

The following examples are meant to illustrate but not limit the present invention.

Example 1

An aqueous solution containing 100 g/l of La as lanthanum chloride is injected in a spray dryer with an outlet temperature of 250° C. The intermediate product corresponding to the spray-drying step is recovered in a bag filter. This intermediate product is calcined at 900° C. for 4 hours. FIG. 12 shows a scanning electron micrograph of the product, enlarged 25,000 times. The micrograph shows a porous structure formed of needle-like particles. The X-Ray diffraction pattern of the product (FIG. 13) shows that it consists of lanthanum oxychloride LaOCl.

To determine the reactivity of the lanthanum compound with respect to phosphate, the following test was conducted. A stock solution containing 13.75 g/l of anhydrous Na₂HPO₄ and 8.5 g/l of HCl was prepared. The stock solution was adjusted to pH 3 by the addition of concentrated HCl. An amount of 100 ml of the stock solution was placed in a beaker with a stirring bar. The lanthanum oxychloride from above was added to the solution to form a suspension. The amount of lanthanum oxychloride was such that the amount of La in suspension was 3 times the stoichiometric amount needed to react completely with the phosphate. Samples of the suspension were taken at time intervals, through a filter that separated all solids from the liquid. The liquid sample was analyzed for phosphorous. FIG. 14 shows the rate of phosphate removed from solution.

Example 2 Comparative Example

To determine the reactivity of a commercial lanthanum with respect to phosphate, the relevant portion of Example 1 was repeated under the same conditions, except that commercial lanthanum carbonate La₂(CO₃)₃.H₂O and La₂(CO₃)₃.4H₂O was used instead of the lanthanum oxychloride of the present invention. Additional curves on FIG. 14 show the rate of removal of phosphate corresponding to commercial lanthanum carbonate La₂(CO₃)₃.H₂O and La₂(CO₃).4H₂O. FIG. 14 shows that the rate of removal of phosphate with the commercial lanthanum carbonate is faster at the beginning but slower after about 3 minutes.

Example 3

An aqueous HCl solution having a volume of 334.75 ml and containing LaCl₃ (lanthanum chloride) at a concentration of 29.2 wt % as La₂O₃ was added to a four liter beaker and heated to 80° C. with stirring. The initial pH of the LaCl₃ solution was 2.2. Two hundred and sixty five ml of an aqueous solution containing 63.59 g of sodium carbonate (Na₂CO₃) was metered into the heated beaker using a small pump at a steady flow rate for 2 hours. Using a Buchner filtering apparatus fitted with filter paper, the filtrate was separated from the white powder product. The filter cake was mixed four times with 2 liters of distilled water and filtered to wash away the NaCl formed during the reaction. The washed filter cake was placed into a convection oven set at 105° C. for 2 hours, or until a stable weight was observed. FIG. 15 shows a scanning electron micrograph of the product, enlarged 120,000 times. The micrograph shows the needle-like structure of the compound. The X-Ray diffraction pattern of the product (FIG. 16) shows that it consists of hydrated lanthanum carbonate hydroxide LaCO₃OH.

To determine the reactivity of the lanthanum compound with respect to phosphate, the following test was conducted. A stock solution containing 13.75 g/l of anhydrous Na₂HPO₄ and 8.5 g/l of HCl was prepared. The stock solution was adjusted to pH 3 by the addition of concentrated HCl. An amount of 100 ml of the stock solution was placed in a beaker with a stirring bar. Lanthanum carbonate hydroxide powder made as described above was added to the solution. The amount of lanthanum carbonate hydroxide powder was such that the amount of La in suspension was 3 times the stoichiometric amount needed to react completely with the phosphate. Samples of the suspension were taken at time intervals through a filter that separated all solids from the liquid. The liquid sample was analyzed for phosphorous. FIG. 17 shows the rate of phosphate removed from solution.

Example 4 Comparative Example

To determine the reactivity of a commercial lanthanum with respect to phosphate, the second part of Example 3 was repeated under the same conditions, except that commercial lanthanum carbonate La₂(CO₃)₃.H₂O and La₂(CO₃)₃.4H₂O was used instead of the lanthanum oxychloride of the present invention. FIG. 17 shows the rate of phosphate removed using the commercial lanthanum carbonate La₂(CO₃)₃.H₂O and La₂(CO₃)₃.4H₂O. FIG. 17 shows that the rate of removal of phosphate with the lanthanum carbonate hydroxide is faster than with the commercial lanthanum carbonate hydrate (La₂(CO₃)₃.H₂O and La₂(CO₃)₃.4H₂O).

Example 5

An aqueous HCl solution having a volume of 334.75 ml and containing LaCl₃ (lanthanum chloride) at a concentration of 29.2 wt % as La₂O₃ was added to a 4 liter beaker and heated to 80° C. with stirring. The initial pH of the LaCl₃ solution was 2.2. Two hundred and sixty five ml of an aqueous solution containing 63.59 g of sodium carbonate (Na₂CO₃) was metered into the heated beaker using a small pump at a steady flow rate for 2 hours. Using a Buchner filtering apparatus fitted with filter paper the filtrate was separated from the white powder product. The filter cake was mixed four times with 2 liters of distilled water and filtered to wash away the NaCl formed during the reaction. The washed filter cake was placed into a convection oven set at 105° C. for 2 hours until a stable weight was observed. Finally, the lanthanum carbonate hydroxide was placed in an alumina tray in a muffle furnace. The furnace temperature was ramped to 500° C. and held at that temperature for 3 hours. The resultant product was determined to be anhydrous lanthanum oxycarbonate La₂O₂CO₃.

The process was repeated three times. In one case, the surface area of the white powder was determined to be 26.95 m²/gm. In the other two instances, the surface area and reaction rate is shown in Table 1. FIG. 18 is a scanning electron micrograph of the structure, enlarged 60,000 times. The micrograph shows that the structure in this compound is made of equidimensional or approximately round particles of about 100 nm in size. FIG. 19 is an X-ray diffraction pattern showing that the product made here is an anhydrous lanthanum oxycarbonate written as La₂O₂CO₃.

To determine the reactivity of this lanthanum compound with respect to phosphate, the following test was conducted. A stock solution containing 13.75 g/l of anhydrous Na₂HPO₄ and 8.5 g/l of HCl was prepared. The stock solution was adjusted to pH 3 by the addition of concentrated HCl. An amount of 100 ml of the stock solution was placed in a beaker with a stirring bar. Anhydrous lanthanum oxycarbonate made as described above, was added to the solution. The amount of anhydrous lanthanum oxycarbonate was such that the amount of La in suspension was 3 times the stoichiometric amount needed to react completely with the phosphate. Samples of the suspension were taken at intervals, through a filter that separated all solids from the liquid. The liquid sample was analyzed for phosphorous. FIG. 20 shows the rate of phosphate removed.

Example 6 Comparative Example

To determine the reactivity of a commercial lanthanum with respect to phosphate, the second part of Example 5 was repeated under the same conditions, except that commercial lanthanum carbonate La₂(CO₃)₃.H₂O and La₂(CO₃)₃.4H₂O was used instead of the La₂O₂CO₃ of the present invention. FIG. 20 shows the rate of removal of phosphate using the commercial lanthanum carbonate La₂(CO₃)₃.H₂O and La₂(CO₃)₃.4H₂O. FIG. 20 shows that the rate of removal of phosphate with the anhydrous lanthanum oxycarbonate, produced according to the process of the present invention is faster than the rate observed with commercial lanthanum carbonate hydrate La₂(CO₃)₃.H₂O and La₂(CO₃)₃.4H₂O.

Example 7

A solution containing 100 g/l of La as lanthanum acetate is injected in a spray-drier with an outlet temperature of 250° C. The intermediate product corresponding to the spray-drying step is recovered in a bag filter. This intermediate product is calcined at 600° C. for 4 hours. FIG. 21 shows a scanning electron micrograph of the product, enlarged 80,000 times. FIG. 22 shows the X-Ray diffraction pattern of the product and it shows that it consists of anhydrous lanthanum oxycarbonate. The X-Ray pattern is different from the pattern corresponding to Example 5, even though the chemical composition of the compound is the same. The formula for this compound is written as (La₂CO₅). Comparing FIGS. 21 and 18 shows that the compound of the present example shows a structure of leaves and needles as opposed to the round particles formed in Example 5. The particles may be used in a device to directly remove phosphate from an aqueous or non-aqueous medium, e.g., the gut or the bloodstream.

To determine the reactivity of the lanthanum compound with respect to phosphate, the following test was conducted. A stock solution containing 13.75 g/l of anhydrous Na₂HPO₄ and 8.5 g/l of HCl was prepared. The stock solution was adjusted to pH 3 by the addition of concentrated HCl. An amount of 100 ml of the stock solution was placed in a beaker with a stirring bar. La₂CO₅ powder, made as described above, was added to the solution. The amount of lanthanum oxycarbonate was such that the amount of La in suspension was 3 times the stoichiometric amount needed to react completely with the phosphate. Samples of the suspension were taken at intervals through a filter that separated all solids from the liquid. The liquid sample was analyzed for phosphorous. FIG. 23 shows the rate of phosphate removed from solution.

Example 8 Comparative Example

To determine the reactivity of a commercial lanthanum with respect to phosphate commercial lanthanum carbonate La₂(CO₃)₃.H₂O and La₂(CO₃)₃.4H₂O was used instead of the lanthanum oxycarbonate made according to the present invention as described above. FIG. 23 shows the rate of phosphate removal for the commercial lanthanum carbonate La₂(CO₃)₃.H₂O and La₂(CO₃)₃.4H₂O. FIG. 23 also shows that the rate of phosphate removal with the lanthanum oxycarbonate is faster than the rate of phosphate removal with commercial lanthanum carbonate hydrate La₂(CO₃)₃.H₂O and La₂(CO₃)₃.4H₂O.

Example 9

To a solution of titanium chloride or oxychloride containing 120 g/l Ti and 450 g/l Cl is added the equivalent of 2.2 g/l of sodium phosphate Na₃PO₄. The solution is injected in a spray dryer with an outlet temperature of 250° C. The spray dryer product is calcined at 1050° C. for 4 h. The product is subjected to two washing steps in 2 molar HCl and to two washing steps in water. FIG. 24 is a scanning electron micrograph of the TiO₂ material obtained. It shows a porous structure with individual particles of about 250 nm connected in a structure. This structure shows good mechanical strength. This material can be used as an inert filtering material in a fluid stream such as blood.

Example 10

The product of Example 9 is re-slurried into a solution of lanthanum chloride containing 100 g/l La. The slurry contains approximately 30% TiO₂ by weight. The slurry is spray dried in a spray dryer with an outlet temperature of 250° C. The product of the spray drier is further calcined at 800° C. for 5 h. It consists of a porous TiO₂ structure with a coating of nano-sized lanthanum oxychloride. FIG. 25 is a scanning electron micrograph of this coated product. The electron micrograph shows that the TiO₂ particles are several microns in size. The LaOCl is present as a crystallized deposit with elongated crystals, often about 1 μm long and 0.1 μm across, firmly attached to the TiO₂ catalyst support surface as a film of nano-size thickness. The LaOCl growth is controlled by the TiO₂ catalyst support structure. Orientation of rutile crystals works as a template for LaOCl crystal growth. The particle size of the deposit can be varied from the nanometer to the micron range by varying the temperature of the second calcination step.

FIG. 26 is a scanning electron micrograph corresponding to calcination at 600° C. instead of 800° C. It shows LaOCl particles that are smaller and less well attached to the TiO₂ substrate. FIG. 27 is a scanning electron micrograph corresponding to calcination at 900° C. instead of 800° C. The product is similar to the product made at 800° C., but the LaOCl deposit is present as somewhat larger crystals and more compact layer coating the TiO₂ support crystals. FIG. 28 shows the X-Ray diffraction patterns corresponding to calcinations at 600°, 800° and 900° C. The figure also shows the pattern corresponding to pure LaOCl. The peaks that do not appear in the pure LaOCl pattern correspond to rutile TiO₂. As the temperature increases, the peaks tend to become higher and narrower, showing that the crystal size of the LaOCl as well as TiO₂ increases with the temperature.

Example 11

An aqueous HCl solution having a volume of 334.75 ml and containing LaCl₃ (lanthanum chloride) at a concentration of 29.2 wt % as La₂O₃ was added to a 4 liter beaker and heated to 80° C. with stirring. The initial pH of the LaCl₃ solution was 2.2. Two hundred and sixty five ml of an aqueous solution containing 63.59 g of sodium carbonate (Na₂CO₃) was metered into the heated beaker using a small pump at a steady flow rate for 2 hours. Using a Buchner filtering apparatus fitted with filter paper the filtrate was separated from the white powder product. The filter cake was mixed four times, each with 2 liters of distilled water and filtered to wash away the NaCl formed during the reaction. The washed filter cake was placed into a convection oven set at 105° C. for 2 hours or until a stable weight was observed. The X-Ray diffraction pattern of the product shows that it consists of hydrated lanthanum carbonate hydroxide LaCO₃OH. The surface area of the product was determined by the BET method. The test was repeated 3 times and slightly different surface areas and different reaction rates were obtained as shown in Table 1.

Example 12

Six adult beagle dogs were dosed orally with capsules of LaCO₃OH (compound A) or La₂O₂CO₃ (compound B) in a cross-over design using a dose of 2250 mg elemental lanthanum twice daily (6 hours apart). The doses were administered 30 minutes after provision of food to the animals. At least 14 days washout was allowed between the crossover arms. Plasma was obtained pre-dose and 1.5, 3, 6, 7.5, 9, 12, 24, 36, 48, 60, and 72 hours after dosing and analyzed for lanthanum using ICP-MS. Urine was collected by catheterization before and approximately 24 hours after dosing and creatinine and phosphorus concentrations measured.

The tests led to reduction of urine phosphate excretion, a marker of phosphorous binding. Values of phosphate excretion in urine are shown in Table 2 below.

TABLE 2 Median phosphorus/creatinine ratio (% reduction compared La Compound to pre-dose value) 10^(th) and 90^(th) percentiles A 48.4% 22.6-84.4% B 37.0% −4.1-63.1%

Plasma lanthanum exposure: Overall plasma lanthanum exposure in the dogs is summarized in Table 3 below. The plasma concentration curves are shown in FIG. 29.

TABLE 3 Mean (sd) Area Under the La Curve_(0-72 h) (ng-h/mL); Maximum concentration C_(max) Compound (standard deviation) (ng/mL); (standard deviation) A 54.6 (28.0) 2.77 (2.1) B 42.7 (34.8) 2.45 (2.2)

Example 13 First In Vivo Study in Rats

Groups of six adult Sprague-Dawley rats underwent 5/6th nephrectomy in two stages over a period of 2 weeks and were then allowed to recover for a further two weeks prior to being randomized for treatment. The groups received vehicle (0.5% w/v carboxymethyl cellulose), or compounds A or B suspended in vehicle, once daily for 14 days by oral lavage (10 ml/kg/day). The dose delivered 314 mg elemental lanthanum/kg/day. Dosing was carried out immediately before the dark (feeding) cycle on each day. Urine samples (24 hours) were collected prior to surgery, prior to the commencement of treatment, and twice weekly during the treatment period. Volume and phosphorus concentration were measured.

Feeding—During the acclimatization and surgery period, the animals were given Teklad phosphate sufficient diet (0.5% Ca, 0.3% P; Teklad No. TD85343), ad libitum. At the beginning of the treatment period, animals were pair fed based upon the average food consumption of the vehicle-treated animals the previous week.

5/6 Nephrectomy—After one week of acclimatization, all animals were subjected to 5/6 nephrectomy surgery. The surgery was performed in two stages. First, the two lower branches of the left renal artery were ligated. One week later, a right nephrectomy was performed. Prior to each surgery, animals were anesthetized with an intra-peritoneal injection of ketamine/xylazine mixture (Ketaject a 100 mg/ml and Xylaject at 20 mg/ml) administered at 10 ml/kg. After each surgery, 0.25 mg/kg Buprenorphine was administered for relief of post-surgical pain. After surgery, animals were allowed to stabilize for 2 weeks to beginning treatment.

The results showing urine phosphorus excretion are given in FIG. 30. The results show a decrease in phosphorus excretion, a marker of dietary phosphorus binding, after administration of the lanthanum compounds (at time>0), compared to untreated rats.

Example 14 Second In Vivo Study in Rats

Six young adult male Sprague-Dawley rats were randomly assigned to each group. Test items were lanthanum oxycarbonates La₂O₂CO₃ and La₂CO₅ (compound B and compound C), each tested at 0.3 and 0.6% of diet. There was an additional negative control group receiving Sigmacell cellulose in place of the test item.

The test items were mixed thoroughly into Teklad 7012CM diet. All groups received equivalent amounts of dietary nutrients.

TABLE 4 Sigmacell Group ID Treatment Test Item cellulose Teklad Diet I Negative control 0.0% 1.2% 98.8% II Compound B - 0.3% 0.9% 98.8% Mid level III Compound B - 0.6% 0.6% 98.8% High Level IV Compound C - 0.3% 0.9% 98.8% Mid level V Compound C - 0.6% 0.6% 98.8% High level

Rats were maintained in the animal facility for at least five days prior to use, housed individually in stainless steel hanging cages. On the first day of testing, they were placed individually in metabolic cages along with their test diet. Every 24 hours, their output of urine and feces was measured and collected and their general health visually assessed. The study continued for 4 days. Food consumption for each day of the study was recorded. Starting and ending animal weights were recorded.

Plasma samples were collected via retro-orbital bleeding from the control (I) and high-dose oxycarbonate groups, III and V. The rats were then euthanized with CO₂ in accordance with the IACUC study protocol.

Urine samples were assayed for phosphorus, calcium, and creatinine concentration in a Hitachi 912 analyzer using Roche reagents. Urinary excretion of phosphorus per day was calculated for each rat from daily urine volume and phosphorus concentration. No significant changes were seen in animal weight, urine volume or creatinine excretion between groups. Food consumption was good for all groups.

Even though lanthanum dosage was relatively low compared to the amount of phosphate in the diet, phosphate excretion for 0.3 or 0.6% La added to the diet decreased as shown in Table 5 below. Table 5 shows average levels of urinary phosphate over days 2, 3, and 4 of the test. Urine phosphorus excretion is a marker of dietary phosphorous binding.

TABLE 5 Urinary phosphate excretion (mg/day) Control 4.3 Compound B = La₂O₂CO₃ 2.3 Compound C = La₂CO₅ 1.9

Example 15

Tests were run to determine the binding efficiency of eight different compounds for twenty-four different elements. The compounds tested are given in Table 6.

TABLE 6 Test ID Compound Preparation Technique 1 La₂O₃ Calcined the commercial (Prochem) La₂(CO₃)₃•H₂O at 850° C. for 16 hrs. 2 La₂CO₅ Prepared by spray drying lanthanum acetate solution and calcining at 600° C. for 7 hrs (method corresponding to FIG. 3) 3 LaOCl Prepared by spray drying lanthanum chloride solution and calcining at 700° C. for 10 hrs (method corresponding to FIG. 1) 4 La₂(CO₃)₃•4H₂O Purchased from Prochem (comparative example) 5 Ti carbonate Made by the method of FIG. 11, where the LaCl₃ solution is replaced by a TiOCl₂ solution. 6 TiO₂ Made by the method corresponding to FIG. 2, with addition of sodium chloride. 7 LaCO₃OH Precipitation by adding sodium carbonate solution to lanthanum chloride at 80° C. (Method corresponding to FIG. 10) 8 LaO₂CO₃ Precipitation by adding sodium carbonate solution to lanthanum chloride solution at 80° C. followed by calcinations at 500° C. for 3 hrs (Method of FIG. 11)

The main objective of the tests was to investigate the efficiency at which the compounds bind arsenic and selenium, in view of their use in removing those elements from drinking water. Twenty-one different anions were also included to explore further possibilities. The tests were performed as follows:

The compounds given in Table 6 were added to water and a spike and were vigorously shaken at room temperature for 18 hrs. The samples were filtered and the filtrate analyzed for a suite of elements including Sb, As, Be, Cd, Ca, Cr, Co, Cu, Fe, Pb, Mg, Mn, Mo, Ni, Se, Tl, Ti, V, Zn, Al, Ba, B, Ag, and P.

The spike solution was made as follows:

1. In a 500 ml volumetric cylinder add 400 ml of de-ionized water.

2. Add standard solutions of the elements given above to make solutions containing approximately 1 mg/l of each element.

3. Dilute to 500 mls with de-ionized water.

The tests were conducted as follows:

1. Weigh 0.50 g of each compound into its own 50 ml centrifuge tube.

2. Add 30.0 ml of the spike solution to each.

3. Cap tightly and shake vigorously for 18 hrs.

4. Filter solution from each centrifuge tube through 0.2 .mu.m syringe filter. Obtain about 6 ml of filtrate.

5. Dilute filtrates 5:10 with 2% HNO₃. Final Matrix is 1% HNO₃.

6. Submit for analysis.

The results of the tests are given in Table 7.

TABLE 7 % Analyte Removed Sb As Be Cd Ca Cr Co Cu Fe Pb Mg Mn La₂O₃ 89 85 97 95 21 100 69 89 92 92 0 94 La₂CO₃ 96 93 100 83 0 100 52 97 100 99 0 99 LaOCl 86 76 89 46 0 100 28 88 100 99 0 28 La₂(CO₃)₃•4H₂O 84 25 41 37 28 94 20 0 56 90 0 20 Ti(CO₃)₂ 96 93 100 100 99 99 99 98 100 98 79 100 TiO₂ 96 93 8 4 0 6 0 11 49 97 0 1 LaCO₃OH 87 29 53 37 28 100 29 10 58 98 0 25 La₂O₂CO₃ 97 92 100 85 21 100 59 98 100 99 0 99 La₂O₃ 89 28 72 8 90 95 95 85 23 0 47 96 La₂CO₃ 98 17 79 8 100 99 100 93 0 0 73 99 LaOCl 94 0 71 13 100 99 24 92 7 0 96 96 La₂(CO₃)₃•4H₂O 98 1 78 5 100 99 16 11 23 0 48 71 Ti(CO₃)₂ 91 98 97 96 24 100 100 92 100 0 99 98 TiO₂ 97 0 97 62 0 86 0 0 0 30 99 66 LaCO₃OH 99 0 79 8 100 99 16 60 26 0 44 74 La₂O₂CO₃ 99 34 81 12 100 99 100 92 23 0 87 99

The most efficient compounds for removing both arsenic and selenium appear to be the titanium-based compounds 5 and 6. The lanthanum oxycarbonates and carbonate hydroxides made according to the process of the present invention remove at least 90% of the arsenic. Their efficiency at removing Se is in the range 70 to 80%. Commercial lanthanum carbonate (4 in Table 6) is less effective.

The tests show that the lanthanum and titanium compounds made following the process of the present invention are also effective at removing Sb, Cr, Pb, Mo from solution. They also confirm the efficient removal of phosphorus discussed in the previous examples.

While the invention has been described in conjunction with specific embodiments, it is to be understood that many alternatives, modifications, and variations will be apparent to those skilled in the art in light of the foregoing description. Accordingly, this invention is intended to embrace all such alternatives, modifications, and variations that fall within the spirit and scope of the appended claims. 

1-7. (canceled)
 8. A method of treating hyperphosphatemia in a mammal, wherein the method comprises administering an effective amount of a composition comprising a rare earth compound selected from the group consisting of crystalline anhydrous La₂O₂CO₃, crystalline anhydrous La₂CO₅, crystalline LaCO₃OH, or a combination thereof, wherein the rare earth compound has a BET specific surface area of at least about 10 m²/g or more and exhibits a phosphate binding of at least 40% of an initial phosphate content after 10 minutes at an initial pH of about 3, at an amount of the rare earth compound 3 times the stoichiometric amount needed to react completely with the phosphate, and wherein the rare earth compound is in the form of particles with a porous structure.
 9. The method of claim 8, wherein the rare earth compound has a BET specific surface area of about 20 m²/g or more.
 10. The method of claim 8, wherein the particles are between about 1 and 1000 microns in size.
 11. The method of claim 8, wherein the particles comprise individual crystals.
 12. The method of claim 11, wherein the crystals are between about 20 nanometers and 10 microns in size.
 13. The method according to claim 8, wherein the composition is administered as an orally ingestible form.
 14. The method according to claim 13, wherein the orally ingestible form is selected from the group consisting of a liquid solution, a liquid suspension, a tablet, a capsule, and a gel gap. 